Inspecting lighting head system and method of operation

ABSTRACT

A system for high-speed inspection is provided. The system includes a digital camera focused on an inspection location and generating image data. An array of light emitting diodes generates light beams, and one or two lenses collimate the light beams. The angle of incidence of the collimated light on an item at the inspection location is greater than approximately 50 degrees, such as to avoid flashing which can be created by coating on the inspection item or other surface effects. The collimating lenses have a center hole and the digital camera is focused on the inspection location through the center hole.

FIELD OF THE INVENTION

The present invention relates to item inspection, and more specificallyto a lighting head system and method that allows a high intensity beamof light to be directed to a small area at an angle of incidence thatavoids flashing or other effects.

BACKGROUND

Item inspection systems are known in the art. Such systems typically usemagnifiers to increase the effective resolution and decrease theeffective picture element resolution area. Such magnification systemssuffer from the drawback that magnification decreases light intensity,which requires more light to be directed to the inspection item. For asmall inspection item, expensive items can be required to createsufficient light intensity. In addition, if the angle of incidence ofthe light, is not controlled, flashing or other effects can occur due tocoatings or other surface conditions of the inspection item that make itdifficult or impossible to identify markings, defect indications, orother items of interest and for which the inspection is being performed.

SUMMARY OF THE INVENTION

In accordance with the present invention, an inspection lighting head isprovided that overcomes known problems with inspection lighting heads.

In particular, an inspection lighting head and method of use areprovided that allows a high intensity light beam to be directed onto asmall area without the need for expensive lighting systems.

In accordance with an exemplary embodiment of the present invention, asystem for high-speed inspection is provided. The system includes adigital camera focused on an inspection location and generating imagedata. An array of light emitting diodes generates a light beam, and acollimating lens receives the light beam from the array of lightemitting diodes (“LEDs”) and forms collimated light. A secondcollimating lens can also be used where necessary to obtain a desiredangle of incidence on the inspection location. The angle of incidence ofthe collimated light on an item 110 at the inspection location isgreater than approximately 50 degrees, such as to avoid flashing whichcan be created by coating on the inspection item or other surfaceeffects.

The present invention provides many important technical advantages. Oneimportant technical advantage of the present invention is a system forincreasing the intensity of light that is provided to a small inspectionarea while controlling the collimating of the light.

Those skilled in the art will further appreciate the advantages andsuperior features of the invention together with other important aspectsthereof on reading the detailed description that follows in conjunctionwith the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagram of a system for focusing a light beam on aninspection item in accordance with an exemplary embodiment of thepresent invention;

FIG. 2 is a top view of an LED array and inspection item in accordancewith an exemplary embodiment of the first invention;

FIG. 3 is the diagram of an digital camera in accordance with anexemplary embodiment of the present invention;

FIG. 4 is a diagram of a system for performing an inspection inaccordance with an exemplary embodiment of the present invention;

FIG. 5 is a flow chart of a method for inspecting coated items inaccordance with an exemplary embodiment of the present invention; and

FIG. 6 is a flow chart of a method for inspecting items in accordancewith exemplary embodiment of the present invention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

In the description that follows, like parts are marked throughout thespecification and drawings with the same reference numerals,respectively. The drawing figures might not be to scale, and certainitems can be shown in generalized or schematic form and identified bycommercial designations in the interest of clarity and conciseness.

FIG. 1 is a diagram of a system 100 for focusing a light beam on aninspection item 110 in accordance with an exemplary embodiment of thepresent invention. System 100 allows light from a light source such asLEDs to be collimated so as to illuminate an inspection item having acoated surface or other surface features at an angle of incidence thatreduces the amount of flashing, such as reflections from the coatedsurface that can interfere with an inspection of the item.

System 100 includes digital camera 102, which includes a sensor arrayand an imaging objective that increases the magnification factor of theimage. In one exemplary embodiment, digital camera 102 can be used toinspect items having a very small size, such as less than 1 millimeterin diameter. For such items, to perform a high speed inspection it maybe necessary to highly illuminate the item in order to magnify the imageof the item by a sufficient amount to read characters on the item.Digital camera 102 allows high speed inspection of a small item tooccur, but typically requires that the item be illuminated with a highdegree of intensity of light so as to generate sufficient image data forinspection to occur.

Inspection system 114 is coupled to digital camera 102. As used herein,the term “couple” and its cognate terms, such as “couples” and“coupled,” can include a physical connection (such as a copperconductor), a virtual connection (such as through randomly assignedmemory locations of a data memory device), a logical connection (such asthrough logical gates of a semiconducting device), other suitableconnections, or a suitable combination of such connections. In oneexemplary embodiment, systems and components are coupled to othersystems and components through intervening systems and components, suchas through an operating system. Communications media can be a local areanetwork, a wide area network, a public network such as the Internet, thepublic switched telephone network, a wireless network, a fiber opticnetwork, other suitable media, or a suitable combination of such media.

Inspection system 114 can be implemented in hardware, software, or asuitable combination of hardware and software, and can be one or moresoftware systems operating on a general purpose processing platform. Asused herein, a hardware system can include discrete semiconductordevices, an application-specific integrated circuit, a fieldprogrammable gate array, a general purpose processing platform, or othersuitable devices. A software system can include one or more objects,agents, threads, lines of code, subroutines, separate softwareapplications, user-readable (source) code, machine-readable (object)code, two or more lines of code in two or more corresponding softwareapplications, databases, or other suitable software architectures. Inone exemplary embodiment, a software system can include one or morelines of code in a general purpose software application, such as anoperating system, and one or more lines of code in a specific purposesoftware application.

Inspection system 114 receives image data from digital camera 102 anddetermines if character data can be recognized from the inspection imagedata of an inspection item 110. In one exemplary embodiment, inspectionsystem 114 can generate notification data if the amount of flashing orother artifacts being generated are hindering or preventing inspectionof items, can generate data that causes collimating lens 106 andcollimating lens 108 to be changed out manually or automatically, cangenerate operator notification data to change out such lenses, canreceive item type data and select collimating lens 106 and collimatinglens 108 based on the type of item, or can perform other suitablefunctions.

LEDs 104 are an array of light emitting diodes that generate light in acircular array or another suitable formations. Collimating lens 106 andcollimating lens 108 collimate the light from LEDs 104 so that thecollimated conical ring-shaped light beam falls onto an inspection siteat a pre-determined angle of incidence. For example, it has beenobserved that the angle of incidence for small items with coatedsurfaces should be equal to or greater than 50 degrees to avoidflashing. Light from inspection item 110 is reflected and is scatteredthrough hole 112 to digital camera 102.

System 100 allows conventional light sources such as LEDS to be used toilluminate small items that may be covered with a coating or have othersurface features that require the angle of incidence of the lightilluminating an item to be controlled. System 100 thus allows high speedinspection of small items to be performed, such as where the image datafrom the item must be magnified by a significant magnification factor inorder to allow the image data to be analyzed to inspect the item.

FIG. 2 is a top view 200 of an LED array and inspection item 110 inaccordance with an exemplary embodiment of the first invention. FIG. 2shows a circular array of LEDs 104 over lenses 106 and 108. Likewise,hole 112 allows inspection item 110 to be seen through the LED array. Inone exemplary embodiment, hole 112 is less than several millimeters indiameter and inspection item 110 is less than one millimeter in size. Asa result of the small sizes of hole 112 and inspection item 110, a highdegree of magnification can be required in order to generate image datato perform inspection of inspection item 110.

FIG. 3 is the diagram of a digital camera assembly 300 in accordancewith, an exemplary embodiment of the present invention. Digital cameraassembly 300 includes digital camera 102, image sensor array 302 andobjective 304.

Image sensor array 302 can be a suitable array of CMOS or other imagesensing devices that create an N×M array of picture elements, where Nand M are integers. In one exemplary embodiment, image sensor array 302can have a response time that is based on the amount of light that iscollected by each picture element, such that to increase the speed ofdigital image generation, it is necessary to ensure that sufficientphotons of light energy are received at each picture element to generateimage data at that picture element.

Objective 304 allows the magnification factor applied to light that isimpinged on image sensor array 302 to be altered, such as to accommodatedifferent inspection item sizes or for other suitable purposes. In oneexemplary embodiment, as a objective's magnification factor increasesthree times, the amount of light received at image sensor array 302decreases nine times accordingly at other things being equal, such thatin order to keep the speed of digital image sensor array 302 constant,it would be necessary to increase the intensity of light on theinspection item up to nine times.

In operation, system 300 allows an image sensor array to receive lightand generate digital image data for inspection of an item. Objective 304allows the magnification factor to be adjusted so as to optimize theamount of magnification for a given item.

FIG. 4 is a diagram of a system 400 for performing an inspection inaccordance with an exemplary embodiment of the present invention. System400 includes inspection system 114 and character recognition system 402,pass/fail system 404, inspection speed system 406, and angle adjustmentsystem 408, each of which can be implemented in hardware, software, or asuitable combination of hardware and software, and which can be one ormore software systems operating on a general purpose processingplatform.

Character recognition system 402 receives a set of image data of an itemand determines whether one or more characters are present in the set ofimage data. In one exemplary embodiment, character recognition systemcan use character matching based on predetermined item types that arebeing inspected, can look for defects or other image data, can comparecharacters based on histogram data for sectors of the image data, or canperform other suitable functions.

Pass/fail system 404 receives a set of image data from digital camera102 or character recognition system 402 and determines whether the itembeing inspected has passed or failed inspection. In one exemplaryembodiment, pass/fail system 404 can receive a set of characters thatare expected to be present on the item being inspected, and candetermine whether character recognition system 402 has returned thatset. In another exemplary embodiment, pass/fail system 404 can determinethe size of defects, whether detected defects from character recognitionsystem 402 fall within permitted bounds for allowable defects, or othersuitable data. Likewise, pass/fail system 404 can generate operatornotification data so that the operator can stop the item inspectionprocess and correct the test data to match the items being inspected,pass/fail system 404 can generate index data to identify the location ofan item or inspection item that has failed inspection, or can performother suitable functions.

Inspection speed system 406 receives character data from characterrecognition system 402 and determines whether the inspection speed canbe increased or decreased. In one exemplary embodiment, if characterrecognition system 402 is generating data that indicates that charactersare not being recognized due to insufficient lighting, inspection speedsystem 406 can generate inspection speed controls that reduce the speedof the inspection, so as to increase the amount of time that eachinspection item is illuminated. In this manner, the amount of lightenergy transmitted to image sensor array 302 can be increased, which canincrease the ability of character recognition system 402 to identifycharacters in the set of image data. Likewise, if character recognitionsystem 402 is generating image data that does not indicate any problemswith a lack of light from the inspection item, inspection speed system406 can increase the inspection speed to a point where the inspectiontime is optimized.

Angle adjustment system 408 receives image data from characterrecognition system 402 and pass/fail system 404 and determines whetherthe angle of incidence on an inspection item is creating flashing orother artifacts. Angle adjustment system 408 can generate operatornotification data to replace one or more of the collimating lens 106 andcollimating lens 108, can automatically select appropriate collimatinglens 106 and collimating lens 108 and install them in the inspectionapparatus, or can perform other suitable functions.

In operation, system 400 allows items to be inspected that are small insize and are being subjected to high magnification factors. System 400can be used where the small items have characters or other markings thatneed to be recognized and also allows the speed of the inspectionprocess to be adjusted based on the amount of light, can generateoperator notification data in the event of flashing or other problemscaused by an improper angle of incidence, and can perform other suitablefunctions.

FIG. 5 is a flow chart of a method 500 for inspecting coated items inaccordance with an exemplary embodiment of the present invention. Method500 is used for small items subject to high magnification factors, suchas where the flashing from a coating of the item can obscure the image.

At 502 light from a light source is collimated as conical ring-shapedlight beam which falls onto an inspection site at pre-determined anangle of incidence. In one exemplary embodiment, a lens having apre-determined collimating angle can be used. The method then proceedsto 504 where light from the light source that has been collimated isfurther collimated. In one exemplary embodiment, a parameters ofcollimating lenses 106 & 108 (focal length, distance between the lenses,and distances to LEDs and to inspection location) can be changed toachieve desirable angle of incidence of light on inspection area. Themethod then proceeds to 506.

At 506 it is determined whether flashing is present. In one exemplaryembodiment, flashing can occur based on the geometric dimensions of theitem being inspected, the coating qualities, the angle of incidence ofthe light, or other such variables. If it is determined at 506 thatflashing is present, then the method proceeds to 510 where the coneangle is adjusted to change the angle of incidence. In one exemplaryembodiment, the cone angle can be adjusted by changing lens sets toadjust the angle of incidence, a light source such as a fiber opticlight source having a controlled angle incidence can be used todetermine the proper angle of incidence and collimating lenses can beselected based upon that angle of incidence or other suitable processescan be used. The method then returns to 502.

If it is determined at 506 that flashing is not present the methodproceeds to 508 and the selected parameters are used for performinginspection of that item. As previously noted, the angle of incidence canvary as a function item, such that each item can be associated with adifferent collimating lens set.

In operation, method 500, allows small items, such as those that havecoated surfaces or other surface features that make inspectiondifficult, to be inspected at high speed, such as by determining whetherflashing is present at levels of illumination that are required togenerate image data of the item at high speed. Method 500 allows theangle of incidence required for different items to be determined andindexed such that the correct angle of incidence can be used for a givenitem.

FIG. 6 is a flow chart of a method 600 for inspecting items inaccordance with exemplary embodiment of the present invention. Method600 begins at 602 where a circular light beam is generated. In oneexemplary embodiment, a circular light beam can be generated by acircular array of LEDs or other conventional and inexpensive lightgenerating sources. In this manner, expensive or special designed lightsources can be avoided. Likewise, other suitable configurations of lightbeams can be generated, such as oblong, square, point, or other suitablelight beams. The method then proceeds to 6.04.

At 604 the circular light beam is collimated as conical ring-shapedlight beam with a pre-determined cone angle. The angle of collimationcan be determined based upon coordination of the collimation with asubsequent collimation stage. The method then proceeds to 606.

At 606 the collimated light beam is further collimated by apredetermined angle. Likewise, a single stage of collimation can be usedwhere suitable. The method then proceeds to 608.

At 608 a coated inspection item is placed in an inspection area. In oneexemplary embodiment, the coated inspection item can be an item havingsmall dimensions, such as less than 1 millimeter in diameter, and canreceive high levels of illumination in order to perform high speedinspection. In this exemplary embodiment, the inspection item can beplaced in the inspection area based on movement by conveyor, robot arm,movement of the image sensor array, or in other suitable manners. Themethod then proceeds to 610.

At 610 image data of the item is generated. In one exemplary embodiment,an image sensor array with a imaging objective can be used to generatethe image data. The generation of image data is based on the amount oflight energy received at each picture element over a period of time,such that the exposure time required to generate the image data is afunction of the amount of light received Since image magnification of asmall item results in decreasing the amount of light received from theitem, image generation speed can be increased by increasing the amountof light provided to the item, as long as such lighting does not resultin flashing or other unacceptable artifacts. The method then proceeds to612.

At 612 the image data is analyzed to detect marking data on the image,such as characters, defects, or other markings. The method then proceedsto 614.

At 614 it is determined whether flashing or other artifacts are present.In one exemplary embodiment, flashing can be determined to be presentwhen image recognition is not possible, based upon histogram data thatis characteristic of flashing or other artifacts, or in other suitablemanners. If it is determined that flashing is present, the methodproceeds to 616 where notification data is generated, such as anoperator message, or instruction data for withdrawal and adjustment ofan angle of incidence, such as by selecting alternate collimatinglenses. The method then proceeds to 618.

At 618 the angle of incidence on the inspection item is changed bychanging parameters of one or more collimating lenses. In one exemplaryembodiment, the collimating lenses can be automatically selected, suchas by robotic assembly, and replaced, a collimating lens set identifiercan be provided to an operator for correction, such as where theoperator has selected the wrong collimating lens set for a given set ofitems that are being inspected, or other suitable processes can be used.The method then returns to 604.

If it is determined at 614 that flashing or other artifacts are notpresent the method proceeds to 620 where it is determined whether themarking data is correct. As previously described, the marking data canbe characters that are present or that are expected to be present on thesurface of the inspection item, can be defects, or other suitablemarkings. If the marking data is correct (e.g., if the expectedcharacters are present or if no defects are detected), the methodproceeds to 624 and pass data is generated. Otherwise, the methodproceeds to 622 where fail data is generated. From 622 the methodproceeds to 626 where the data is stored. In one exemplary embodiment,the data can be indexed so that the failed item can be removed after atray, array, tube, or other set of inspection items has been inspected.Likewise, operator notification data can be generated if the failuredata indicates that an improper item type has been selected such thatimproper inspection procedures are being used for the item. The methodthen proceeds to 628 where the next item to be inspected is brought intothe inspection area and the method returns to 608.

In operation, method 600 allows items to be inspected, such as smallitems with surface coatings that can create flashing and that requirelight to be provided at high intensities and at pre-determined angles ofincidence. Method 600 thus allows small items to be inspected at highspeeds without flashing effects resulting in erroneous inspectionfailure data.

Although exemplary embodiments of a system and method of the presentinvention have been described in detail herein, those skilled in the artwill also recognize that various substitutions and modifications can bemade to the systems and methods without departing from the scope andspirit of the appended claims.

1-20. (canceled)
 21. A system for high-speed inspection comprising: adigital camera generating image data; an array of light emitting diodes;a collimating lens collimating light from the array of light emittingdiodes on an inspection location; and wherein the collimating lens has atop, a bottom, and a perimeter and the array of light emitting diodes isdisposed around the perimeter of the collimating lens.
 22. The system ofclaim 21 wherein the collimating lens further comprises one or moreadditional collimating lenses to obtain a predetermined angle ofincidence of the collimated light.
 23. The system of claim 21 whereinthe collimating lens has a center and the digital camera is focused onthe inspection location through the center.
 24. The system of claim 21wherein the digital camera applies a high optical magnification factor,and the collimated light increases a light intensity on the inspectionlocation to allow an exposure time required for the digital camera togenerate the image data to be decreased.
 25. The system of claim 21further comprising an inspection item having a compound surface, whereinan angle of incidence of the collimated light reduces flashing from thecompound surface.
 26. The system of claim 21 wherein the inspectionlocation is circular having a diameter smaller than 1 mm.
 27. The systemof claim 21 further comprising an inspection system receiving the imagedata and identifying one or more markings on a surface of an inspectionitem.
 28. The system of claim 21 further comprising: a characterrecognition system receiving the image data and identifying one or morecharacters in the image data; and a pass/fail system generatingpass/fail data for an inspection item based on the one or morecharacters or an absence of the one or more characters.
 29. A system forhigh-speed inspection comprising: a digital camera focused on aninspection location; an array of light emitting diodes; a collimatinglens having a top, a bottom, and a hole at the center, wherein the arrayof light emitting diodes is disposed at the top of and around aperiphery of the collimating lens, the collimating lens receiving lightfrom the array of light emitting diodes and emitting collimated light;an inspection item having a compound on a surface of the inspectionitem, the inspection item disposed at the inspection location; andwherein the digital camera is focused on the inspection item through thehole of the collimating lens.
 30. The system of claim 29 wherein anangle of incidence of the collimated light on the inspection itemmitigates flashing caused by the compound on the surface of theinspection item.
 31. The system of claim 30 wherein the angle ofincidence is greater than approximately 50 degrees.
 32. A method forinspecting an item comprising: generating light from a light source;collimating the light so as to direct the collimated light onto aninspection site at a predetermined angle of incidence to mitigateflashing from an inspection item having a surface coated with acompound.
 33. The method of claim 32 further comprising generatingdigital image data of the inspection item at a high speed, wherein thecollimated light reduces a time required to generate the digital imagedata of the inspection item by increasing a light intensity on theinspection item.
 34. The method of claim 32 wherein generating the lightcomprises generating a ring-shaped light beam from an array of lightemitting diodes.
 35. The method of claim 32 wherein collimating thelight comprises providing a second collimating lens between thecollimated light and the inspection item to collimate the light at thepredetermined angle of incidence.
 36. The method of claim 32 wherein thepredetermined angle of incidence is greater than 50 degrees.
 37. Themethod of claim 32 further comprising: generating digital image data ofthe inspection item and detecting data from the surface of theinspection item underneath the compound in the digital image data. 38.The method of claim 32 further comprising: generating image data of theinspection item using a camera; and detecting data from the inspectionitem in the image data.
 39. The method of claim 32 wherein a tip of aconical ring-shaped light beam from the light source has a diametersmaller than 1 mm.
 40. The method of claim 32 further comprising:generating image data of the inspection item using a digital camera;detecting marking data from the inspection item in the image data; andgenerating an indication if the marking data does not matchpredetermined marking data.